Jet propelled airplane with wing discharge slot



1949 w. P. GOEMBEL 2,479,487

JET PROPELLED AIRPLANE WITH WING DISCHARGE SLOT Filed Jan. 28, 1946 2 Sheets-Sheet 2 INVENTOR.

WZZZZ'QmBQ'OemZ'eZ ATTORNEYS Patented Aug. 16, 1949 i i m :B iliefi beb l vitiii oie1M!!- pnliqe na 28, v fiexia No: 13 871 2 Q ims- 244-15) E WZTH W NG:-

M imze t onz, ela s 9 ipnr veme is i @127 r s mem- Th s f ring b hind a ircu a tube plan and oth r evice in Q hin ii n iss mn y expr ssed byssym mat' imum edge i is as pr p l ing usta nin Gem-2 .198. mi sfi fim s'ed ed- A no el of th i v n on other means. si ply expressed by saying that; the trailing edge h principal bi ci i m inven on amq a see airtoils. b eliminated. The hisother thin s, is to provid a mp oi e method on. of. a oil develo ment. as een. n uence of propulsion, ipgircraft, atercraft -0th?! W e necessi y oi gr te th of ai -mil at d vicesnevigable through air or water. For pm: the rear spar location for structural reasons, poses of simplicity of illustration I shall refer lh p n g edgev or the n; of airfqfl afflot the here n to rafi wiiho tl i 'it n my inv i 1 wa war ppsti n m y belcpnsiclfere a a ai c fl s de es I alir fer t @iei 111s Po tha referre to above, which r s flui e thea ur t t e flu d i dim s ins: drag Q si i i Ano her umqse o a e 9r unwise- 1: n the illustil I ihistsi ng 9i c niovl q or trailin ge ecti n. bas n o re 'l ea ns iqazircm i Fil is}? is to in the dqwnwarq q i n q e f a n -ms 4 1 91 QK QR Q, ai i ai'estn airfioil. "This a ma i 0? an?! gi 11' s am. his. increasem lift by downwar'dq Amther of myenfimi P n; I have accomplishe n a new. bri imu 3 PIQ jet mi 11 a m n a t f ueflgl in per. I eliminate the less eflf ieient veliciiy 110W Wm ilemdylleme i e sect on or he 'sirfoiras'it. isf'ge'is hasbeco ne wellkn vyn as g typ; o1; ho d-. y n .5 memo-re m layer My mlegtigp includ wars peril Sne l a Seamin mutilat'iqri bf. in plfovgme'nt'fi thfifigl-rgdyganncbog airfoil w ulil lliawev a very bllinii onsevei ed bod}? mann r to. lff lm the r l iesms sn i 24 s 9! b1 11" d Eig'uie 3 shows the ohihi urfaces; l. ,l r further i i Oi m emes to Q Q QQ i ff giifigfigich ffi i a i d ifi fi uiie le me ns, o qqn rp l n ins l i in" direohe Emil gfib 5 m EM; Illa-K t F 9 t d be qme that of 9m as 293 at 129191 5 and s a of; m

1 9? and/ r Yelgcit lin, such; m g et as in rease the sef lhigss 0? s c Me T the n esq n 9 .isq 'si tbelffi. wh ch, ma e i a r more ll app9 1;,tl; V j s stsp e. nov l. qpsiruqtipn comb. a an ent of Peril -.7 a? w ll. e. mo e i l ied t9 a d i lu trated the es mnp e 3- bovgs me flow ahonizl a, conventional &in q b pho aph n v fl: stream. The boundary eswasd o 85. a d separation r g5; 'lg'h is leayes anegative pressure 1 neg-ion indicated by small-circles: claimed; degg; gin lgegion indicates high drag espe drawings: c allg at, lngl; speeds. Flue inadequacy of the smgui 1 is d-fmgmentaxy mgllmgw 9i analk 1;; mpg edge of conventlonal airfoils is here ,sne'savm J-et ron i si i w n q' clhf si ts 41? m The i semen conestructed:acordihgtp mbggmitit gigs, in fill ng the dead an: space 1s obviously invention, 7 lll'ssillfi llli- "Figure2 is a sectional iew taken on the line Figure illustrates f mvemlon f 9? angles of Figure-1 dl'fib tn det us fw f of attack under conditmns similar to those in t u t b 45 Figure 3. The boundary layer. maybecome 'Flgure'e illustrates air flow about a, comma; Slightly thicker 5' d u s ee er tional irfofl; tion does not occur. The boundai ylayer is gay F ur 4 mustmtgs flow almug atlrfgn erg ized by a suction due to the l igher'velocity n f c w fiin PTfi is invle i on, thelei e in e we 1 nd 364 in a man: Ii is l m n ha the zw i par o lead? qrewiegs ut b s t e iqelisiwl i nen-simila; to thgit in the co nnion iniecto f In in edge of an ir oi mere i fiq ems is Figure 3 e he: i th r ion. v-dra nr iiu ing, ami al y than the after art r r l ed negative Pressure region hich is. elim nated in the airfoil, It'is also well known t1 V 7 i s sire inin r u ar iub s am :9: PQSiti /e nzessuie esqi l nvieicm hi i n sli e? the i s s iise 9 ies 9; such time eii qil 9? new desi iih- 12 1919 velocity:

distribution, the wake can be controlled to ad- We now have a wing with thrust instead of drag when the jet is properly applied. For takeoff and climb and high speed with the jet properly applied an airplane equipped with this wing would behave in a manner similar to conventional airplanes, and for the gliding and landing conditions it behaves, without the jet, in a manner similar to a conventional airplane with deflected flaps. If in flight a power failure occurs thepilot has an airplane similar to one. with deflected flaps, and is relieved of that operation.

In Figure 4, the contour may represent the forward part of a conventional airfoil, or any suitable airfoil section developed for use in con-- junction with an afterbody jet. This combination is a basic part of my invention. The principle of the reaction jet is well understood. The principle is understood that a fast moving stream with slower moving streams on each side induces a flow from the slow streams to the faster stream. The jet beingthe fastest stream induces a greater velocity of flow about the airfoil, which increases the lift. The reaction of the jet produces a thrust on the airfoil.

Others havesuggested the use of a reaction jet of small orifice. area having very high pressure and very high velocity and locating the jet at the rear of anaerodynamic body. I improve sucha combination by. increasing the orifice area and reducing the velocity. This improvement increases the efficiency of the reaction jet. I accomplish. this by using a diverging chamber the outlet of which forms an orifice of increased area. I also use other means as revealed hereafter. The reaction jet used by others results in thrust or propulsion. I further improve the reaction jet by controlling it in direction which varies the function from thrust on the device to lift on the device. For example, assuming the device is an airplane in flight, jets used and proposed by others produce thrust and are propelling devices. Their airplanes depend on conventional devices or common airfoils for lift in horizontal, climbing and gliding flight. In horizontal and climbing flight their main. jet is functioning principally as a propeller. The source of power is shut off, or nearly so, in gliding flight. In their airplanes the direction of the main jet with respect to the principal axis of the airplane remains fixed. In my jet propelled airplane the direction of the jet does not remain fixed with respect to the principal axis but is adjustable in its direction. This adjustment, when used in conjunction with other parts of the airplane, results in forces being applied in other than the flight direction. Elsewhere in this disclosure I speak of a downward deflection of the main jet as increasing the lift. The downward deflection changes the jet direction with respect to the principal axis of the airplane. Increasing the lift means increasing the vertical force. In this case the increase is due to downward deflection of the air behind the airfoil or aerodynamic reaction, and also due to the action of the jet which increases the mass or volume of the 4 downwash and in'so doing the component of the jet reaction, with respect to the axis of the airplane, is increased. If the jet is deflected upward a loss of lift occurs but a corresponding loss of drag or gain in thrust is experienced up to a certain point. The above adjustment or control of the main jet is in some ways analogous to changing the angle of attack through small angles in conventional airplanes; however, as is seen above I accomplish the same results without changing the angle of attack, but by changing the angle of the main jet.

With my high lift devices I get a greater angle of stall and greater lateral control which permits a stalling, power on, glide of very steep descent unlike the power-off glide of jet propelled airplanes used and proposed by others. Jets of very small orifice height, and of small orifice area, have been placed in various locations along the upper contour of conventional airfoils. Note here that my use of the main jet implies a jet of greater orifice area, than has been suggested, and of lower relative velocities, which gives higher jet efiiciency.

My invention provides means of controlling the reaction jet in direction and/or velocity. One means, among others, is by the use of movable surfaces. I shall for simplicity herein refer to such movable surfaces as vanes.

The deflection of the let in a downward direction increases the downwash angle and downwash volume of the wing and deflects downward the lower flow. The upper boundary of the jet becomes more nearly parallel to the upper flow and increases the velocit of theflow over the upper surface, thus increasing the lift. Figures 3. and 2 illustrate my invention of an airfoil in combination with a pumped jet discharging rearward between vanes or surfaces. The fuselage or body of the airplane is generally indicated by the reference numeral Hi. It should be understood however, that this invention could be embodied in the type of airplane referred to .as a flying wing. That is, an airplane containing all of its equipment and structure withinthe'wing alone. A turbo-jet ll is contained. in the fuselage i0 and is'provided with a forwardly facing air intake 12. A turbo-jet engine is shown merely for illustrative purposes since any of the well known devices such as ram jets or air compressors could be substituted without departing from the basic concepts of my invention. A pair of branch conduits or ducts are joined to the exhaust of the engine II and bend outwardly to extend along th length of each of the wings l3. The wing i3 is formed, in the embodiment here illustrated, of a main tubular structural member 14, metal skin l6, and upper and lower transverse stiffening members I 5. The rear edge of the wing 13 is supported by the spar caps 39 which are joined to the upper and lower trailing edges of the skin iii. A longitudinall extending slot 41 is formed in the rear of the duct and the upper and lower edges of the slot 4'! are joined to the adjacent spar caps 39, thus communicating the space between the spar caps with the interior of the duct 45. An upper vane 38, and a lower vane 43 are rockably carried by the upper and lower spar caps 39 respectively. 1 The vanes 38 and 43 are disposed to the rear of the caps 39 and are mounted on the hinge members 35, best seen in Figure 1. For the vanes I prefer an airfoil surface such as shown in Figure 2. It will be noted that there is a space between the upper vane 38 and the surface of member 39 which may be open at all times. This small bypathed jet 4!! aids in delaying separation and energize the upper boundary layer. Moving the vane 38 from position 4| to position 42 deflects the main jet downward. The lower vane 43 on being deflected downward acts very much as a deflected flap without the high drag if the main jet is functioning. Under these conditions the airfoil is more efiicient for take-off and climb The vanes may work in unison or have varying degrees of differential movement. The vanes may be operated manually and/or automatically. The vanes may extend over the entire span or part of the span.

Considering the jet speed as full on at the source, deflecting the upper and lower vanes 38 and 43 in Figure 2 inward would tend to increase the jet velocity, and the speed of the airplane depending on the design. On the other hand it can be stated that deflecting the upper and lower vanes outward in the manner of a diffuser increases the thrust and therefore the speed of the airplane. Either may be true but depending on the design. As an example, assuming the jet mass as constant, if the vanes in the above consideration were long in chord, any great deflection outward with respect to each other would cause excessive drag and regardless of increased jet efiiciency the speed of the airplane would be reduced. This condition involves the ability of the jet to follow the walls and the resistance of the vanes when extending too far beyond the airfoil contour.

I include the diffuser in my invention as it is useful in increasing the efficiency of a jet by decreasing the velocity and increasing the pressure. In Figure 2 the inside walls of vanes 38 and 43 act as a diffuser, the efficiency of the diffuser being increased by sucking the boundar layer of the jet into holes 44 through the inner surfaces of the diffuser. This causes the jet to expand much more rapidly and at greater angles than it would in a common diffuser without suction. The jet expansion produces greater thrust. The suction is created by pumps, injectors, or other means indicated by reference numeral 25 in Figure 1.

Figure 2 contour may be that of an airplane wing or the contour of a streamlined structure supporting a landing gear, or any other devices. I mention a landing gear in particular because modern high speed airplanes are quite complicated by the landing gear retraction. My invention of using a jet in combination with such structure results in a thrust and there is no necessity for gear retraction leaving the pilot free of that operation. The construction here disclosed may also be used in place of the conventional fin and rudder or horizontal stabilizer and elevator. The deflection of the vanes 38 and 43 would effect the pitch or yaw of the airplane by directing the jet as desired. The parts 45 are structural members, not necessarily formed as shown, which act as walls of internal ducts. The ducts have openings to allow the escape of the jet and guide vanes as 46 carried b the spar caps 39 to direct and control the jet. Spar caps 39 are structural members of any suitable sectional shape which may be varied to assist in the directing or curving of the fluid flow.

The exact configuration illustrated is regarded as the optimum but some of the desirable results inherent in this disclosure may be obtained by various slight modifications including some departure from the exact configuration shown, and it is, therefore, rejuested that the scope of the invention should be regarded as limited only by the terms of the claims.

What I claim is:

1. In combination with an airplane, means effecting a relative flow of fluid in said airplane, a wing on said airplane, said wing including upper and lower surfaces having verticall spaced apart trailing edges forming a spanwise opening, ver tically spaced upper and lower transverse spar members supporting said wing at said trailing edges, a spanwise extending hollow vane having an airfoil cross section rockably carried by each of said spar members and rearwardly thereof to provide means for varying the height and shape of said opening, a. spanwise duct in said wing having one end in communication with said first mentioned means, a longitudinal slot formed in said duct, the edges of said slot engaging said upper and lower spar members whereby said spar members communicate said duct with said spanwise opening, and a plurality of verticall disposed louvers rockably carried at the opposite ends thereof by said spar members for controlling the lateral direction of the fluid flowing from said duct through said spanwise opening.

2. A device as set forth in claim 1 in which the confronting inner surfaces of said hollow vanes are provided with a plurality of chordwise and spanwise spaced apart openings, and means for producing a low pressure is communicated with the interior of said vanes whereby the boundary layer of fluid flowing along the inner surfaces of said vanes will be caused to adhere closely to said inner surfaces.

WILLIAM PHILIP GOEMBEL.

REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 1,580,577 Baumann Apr. 13, 1926 1,723,479 Goodrich Aug. 6, 1929 1,764,842 Jones June 17, 1930 1,772,196 Wallace Aug. 5, 1930 1,775,757 Gay Sept. 16, 1930 1,837,901 Fottinger 1 Dec. 22, 1931 2,041,791 Stalker May 26, 1936 2,075,817 Loerke Apr. 6, 1937 2,380,535 McDevitt July 31, 1945 2,388,247 Berkow Nov. 6, 1945 2,396,911 Anxionnaz Mar. 19, 1946 2,408,788 Ludington Oct. 8,1946 2,420,323 Meyer May 13, 1947 2,430,431 Lanier Nov. 4, 1947 FOREIGN PATENTS Number Country Date 325,002 Great Britain Feb. 10, 1930 390,363 Great Britain June 6, 1933 427,017 Great Britain Jan. 9, 1934 504,539 Great Britain Apr. 26, 1939 518,663 Great Britain Mar. 5, 1940 865,393 France Feb. 24, 1941 877,590 France Sept. 7, 1942 

